Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification
The huge amount of energy consumed in data centers has prompted researchers to continue studying how to improve their energy efficiency, and according to a US Environmental Protection Agency report, the energy consumption in data centers is doubling every five years; in contrast, the energy consumpt...
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| Format: | Article |
| Language: | zho |
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Journal of Refrigeration Magazines Agency Co., Ltd.
2018-01-01
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| Series: | Zhileng xuebao |
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| Online Access: | http://www.zhilengxuebao.com/thesisDetails#10.3969/j.issn.0253-4339.2018.03.013 |
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| author | 胡雨 耿云 张忠斌 张萌 姚喻晨 黄虎 黄毅 蒋赟昱 |
| author_facet | 胡雨 耿云 张忠斌 张萌 姚喻晨 黄虎 黄毅 蒋赟昱 |
| author_sort | 胡雨 |
| collection | DOAJ |
| description | The huge amount of energy consumed in data centers has prompted researchers to continue studying how to improve their energy efficiency, and according to a US Environmental Protection Agency report, the energy consumption in data centers is doubling every five years; in contrast, the energy consumption in data centers in China have a growth rate significantly higher than the average level globally. Improving the efficiency of the refrigeration system and optimizing the data center airflow pattern will minimize the energy consumption. This paper is the second part of an investigation aiming to find a more satisfying airflow pattern in a data center and to help provide servers with a safer and more reliable operating environment. Based on the simulation described in Part I, the optimal model, including six groups of duct structures, is verified. The odd-numbered sub-modules of the data center were taken as the measured objects, changing the perforation rate of the floor, and the angle of the baffle, to obtain the six groups of reasonable airflow patterns. A comparison of the two key parameters of the front door air supply, namely, the speed and temperature, proves the reliability of the simulated airflow. The maximum relative deviation between the measured and simulated velocity is 17%, and the maximum relative deviation of temperature is 5%, which shows that the simulated temperature and velocity fields are in agreement with the measurement. Concerning the data center heat flux density and energy consumption, the air supply conditions of the cooling system are changed to achieve a comparative analysis of the temperature field under various working conditions. The return air temperature index (RTI) is employed as an evaluation indicator to find that the recommended air supply temperature range, which is 16–19 ℃. The results of this investigation can provide reference for the design of a data center using an under-floor air distribution. |
| format | Article |
| id | doaj-art-346e8a5cd1674aafb440809c82de57e1 |
| institution | DOAJ |
| issn | 0253-4339 |
| language | zho |
| publishDate | 2018-01-01 |
| publisher | Journal of Refrigeration Magazines Agency Co., Ltd. |
| record_format | Article |
| series | Zhileng xuebao |
| spelling | doaj-art-346e8a5cd1674aafb440809c82de57e12025-08-20T03:15:54ZzhoJournal of Refrigeration Magazines Agency Co., Ltd.Zhileng xuebao0253-43392018-01-013966509839Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification胡雨耿云张忠斌张萌姚喻晨黄虎黄毅蒋赟昱The huge amount of energy consumed in data centers has prompted researchers to continue studying how to improve their energy efficiency, and according to a US Environmental Protection Agency report, the energy consumption in data centers is doubling every five years; in contrast, the energy consumption in data centers in China have a growth rate significantly higher than the average level globally. Improving the efficiency of the refrigeration system and optimizing the data center airflow pattern will minimize the energy consumption. This paper is the second part of an investigation aiming to find a more satisfying airflow pattern in a data center and to help provide servers with a safer and more reliable operating environment. Based on the simulation described in Part I, the optimal model, including six groups of duct structures, is verified. The odd-numbered sub-modules of the data center were taken as the measured objects, changing the perforation rate of the floor, and the angle of the baffle, to obtain the six groups of reasonable airflow patterns. A comparison of the two key parameters of the front door air supply, namely, the speed and temperature, proves the reliability of the simulated airflow. The maximum relative deviation between the measured and simulated velocity is 17%, and the maximum relative deviation of temperature is 5%, which shows that the simulated temperature and velocity fields are in agreement with the measurement. Concerning the data center heat flux density and energy consumption, the air supply conditions of the cooling system are changed to achieve a comparative analysis of the temperature field under various working conditions. The return air temperature index (RTI) is employed as an evaluation indicator to find that the recommended air supply temperature range, which is 16–19 ℃. The results of this investigation can provide reference for the design of a data center using an under-floor air distribution.http://www.zhilengxuebao.com/thesisDetails#10.3969/j.issn.0253-4339.2018.03.013data centerair duct layoutexperimental verificationair-supply temperaturereturn temperature index(RTI) |
| spellingShingle | 胡雨 耿云 张忠斌 张萌 姚喻晨 黄虎 黄毅 蒋赟昱 Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification Zhileng xuebao data center air duct layout experimental verification air-supply temperature return temperature index(RTI) |
| title | Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification |
| title_full | Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification |
| title_fullStr | Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification |
| title_full_unstemmed | Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification |
| title_short | Effect of Air Duct Layout on the Airflow in Data Center Using Under-floor Air Distribution (2) Experimental Verification |
| title_sort | effect of air duct layout on the airflow in data center using under floor air distribution 2 experimental verification |
| topic | data center air duct layout experimental verification air-supply temperature return temperature index(RTI) |
| url | http://www.zhilengxuebao.com/thesisDetails#10.3969/j.issn.0253-4339.2018.03.013 |
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